06-1350/Homework Assignment 3: Difference between revisions

06-1350/Navigation Panel   # Week of... Links 1 Sep 11 About, Tue, Thu 2 Sep 18 Tue, Kurlin(P), Thu 3 Sep 25 Tue, Photo, Thu 4 Oct 2 HW1, Tue, Thu 5 Oct 9 Tue(P), Thu(P) 6 Oct 16 HW2, Tue(P), Thu(P) 7 Oct 23 Tue(P), Thu 8 Oct 30 HW3, Tue, Thu 9 Nov 6 Tue (${\displaystyle \nu }$), Thu 10 Nov 13 Tue, Thu 11 Nov 20 HW4(P), Thu 12 Nov 27 Thu 13 Dec 4 Syzygies in Asymptote, Final Jan 8 Grades Note. (P) means "contains a problem that Dror cares about". Add your name / see who's in! On to 07-1352

Solve the following problem and submit your solution in class by November 16, 2006:

Problem. The product of two polynomials is again a polynomial; there must be an analog for that in the world of "polynomial" invariants of knots.

1. Prove that the product of two finite type invariants (of, say, knotted ${\displaystyle \Gamma }$'s) is again a finite type invariant. Of what type will it be, as a function of the types of the two factors of the product?
2. In what way does the product of finite type invariant induces a map ${\displaystyle \Box :{\mathcal {A}}(\Gamma )\to {\mathcal {A}}(\Gamma )\otimes {\mathcal {A}}(\Gamma )}$?
3. Describe the map ${\displaystyle \Box }$ of above in explicit terms. First use the "chords and 4T" description of ${\displaystyle {\mathcal {A}}(\Gamma )}$, and then the "trivalent diagrams and AS, IHX and STU" description of the same object.
4. Learn somewhere about coalgebras and show that ${\displaystyle \Box }$ is always coassociative and cocommutative.
5. Learn somewhere about bialgebras (Hopf algebras without an antipode) and show that ${\displaystyle {\mathcal {A}}(\bigcirc )}$ becomes a commutative associative cocommutative and coassociative bialgebra, if taken with the "connected sum" product and with ${\displaystyle \Box }$ as a coproduct.

With a tiny bit of further algebra and quoting an old theorem of Milnor and Moore, it follows that ${\displaystyle {\mathcal {A}}(\bigcirc )}$ is a commutative graded polynomial algebra with finitely many generators at each degree. The dimension of the spaces of generators at degrees up two 12 are known and are denoted ${\displaystyle \dim {\mathcal {P}}_{m}}$ in the table below, which is reproduced from 06-1350/Class Notes for Thursday October 12:

m	0	1	2	3	4	5	6	7	8	9	10	11	12
${\displaystyle \dim {\mathcal {A}}_{m}^{r}}$	1	0	1	1	3	4	9	14	27	44	80	132	232
${\displaystyle \dim {\mathcal {A}}_{m}}$	1	1	2	3	6	10	19	33	60	104	184	316	548
${\displaystyle \dim {\mathcal {P}}_{m}}$	0	1	1	1	2	3	5	8	12	18	27	39	55